Measuring cell for electrochemically detecting a gas

ABSTRACT

The invention is directed to a measuring cell for electrochemically detecting a gas sample and has at least one measuring electrode and one counter electrode disposed in a housing defining a chamber filled with an electrolyte. The measuring cell also includes a protective disc which is at least partially permeable and is improved so that the configuration of the measuring cell is substantially simpler and is of reduced volume without reducing the ion mobility in the electrolyte and with a significant supply of the electrolyte. The counter electrode is in the form of a layer and is applied to a region of the protective disc facing toward the electrolyte. this region is impermeable to the gas sample and the electrolyte. The counter electrode is further electrically insulated from the measuring electrode and is in permanent contact with the electrolyte. Only the measuring electrode and the diffusion membrane are applied to a region of the protective disc which is permeable to the gas sample.

FIELD OF THE INVENTION

The invention relates to a measuring cell for electrochemicallydetecting a gaseous sample. The measuring cell defines an electrolytechamber filled with an electrolyte and has at least one measuringelectrode and one counter electrode. The cell also includes a diffusionmembrane having an inner surface facing toward the electrolyte. Thediffusion membrane is impermeable to the electrolyte and permeable tothe gas sample. The measuring electrode is in the form of a layer and isapplied to the inner surface of the membrane. The diffusion membrane hasan outer surface facing toward the gas sample and the measuring cellincludes a partially permeable protective disc covering the diffusionmembrane at the outer side thereof.

BACKGROUND OF THE INVENTION

A measuring cell of the kind described above is disclosed in BritishPatent 1,344,616.

The known measuring cell includes an electrolyte chamber accommodatingthe measuring electrode and the counter electrode. The measuringelectrode is applied as an electrically-conductive layer to the backsurface of a diffusion membrane facing the electrolyte. The diffusionmembrane is protected on the side thereof facing the ambient againstmechanical influences by a permeable protective disc. It is necessary toprovide an adequately large supply of electrolyte in order thatmeasuring cells of the above-mentioned type are operationally andmeasurement ready over an adequately long time duration. The chargecarriers generated at the boundary interface "electrolyte/measuringelectrode/gas sample" diffuse in the electrolyte supply between themeasuring electrode and the counter electrode. Accordingly, a good ionmobility is required for an adequate response time for measuring cellsof this type to thereby prevent the premature exsiccation orconcentration of the electrolyte. This increases the size of suchmeasuring cells so that especially portable measuring apparatus becomeinconvenient to handle.

Published British patent application 2,094,005 discloses that theelectrodes in the form of layers are brought as close to each other aspossible. This compact electrode arrangement is however achieved with acomplex wick configuration which makes it possible to bring thenecessary electrolyte to the surface of the measuring electrode from theelectrolyte supply.

SUMMARY OF THE INVENTION

It is an object of the invention to improve a measuring cell of the kinddescribed above so that the construction of the measuring cell issubstantially simpler with a significant electrolyte supply. It isanother object of the invention to provide such a measuring cell havinga reduced volume without reducing the ion mobility in the electrolyte.

The measuring cell of the invention is for electrochemically detecting agas sample. The measuring cell includes: a housing having an openingdirected toward the gas sample to be detected and defining anelectrolyte chamber; an electrolyte contained in the chamber; ameasuring electrode and a counter electrode disposed in the chamber soas to be in spaced relationship to each other; a diffusion membraneinterposed between the opening and the electrolyte and being permeableto the gas sample; the diffusion membrane being impermeable to theelectrolyte and having a lower surface facing the electrolyte; themeasuring electrode being configured as a measuring electrode layerapplied to the lower surface of the membrane; the membrane having anupper surface facing toward the gas sample; a protective disc interposedbetween the opening and the upper surface of the diffusion membrane; theprotective disc having a first component region permeable to the gassample and a second component region impermeable to the gas sample andto the electrolyte; the second component region having a lower surfacearea facing toward the electrolyte and the counter electrode beingconfigured as a counter electrode layer applied to the lower surfacearea of the second component region; the counter electrode layer beingelectrically isolated from the measuring electrode and being inpermanent electrical contact with the electrolyte; and, the measuringelectrode layer and the diffusion membrane being applied to the firstcomponent region of the protective disc.

According to a feature of the measuring cell of the invention, thecounter electrode is in the form of a layer and is applied to acomponent region of the protective disc which is impermeable to theelectrolyte and to the gas sample. The counter electrode is electricallyinsulated from the measuring electrode and is in permanent contact withthe electrolyte. Only the measuring electrode together with thediffusion membrane is applied to a region of the protective disc whichis permeable to the gas sample.

The advantage of the invention is seen essentially in that the measuringelectrode as well as the counter electrode are mounted next to eachother in a close spatial arrangement and are in direct contact with theelectrolyte. In this way, a short diffusion path makes a rapid responsetime possible with very high measuring gas concentrations. A smallconstruction volume of the measuring cell is made possible by thelayer-like arrangement on one and the same surface of the protectivedisc. The electrolyte supply can be extended and prevents an exsiccationof the electrolyte even with longer operating durations.

If it is intended to operate the measuring cell in a potentiostaticoperating mode, then the required reference electrode can be placed inthe same manner directly adjacent to the remaining electrodes in theform of a layer on the electrolyte side of the protective disc.

During operation with or without the reference electrode, thepermeability of the protective disc is only provided in that regionwhich lies opposite the measuring electrode. The gas to be investigatedpasses through the protective disc in its permeable region and diffusesthrough the membrane as well as the permeable measuring cell to thecontact interface "electrolyte/measuring electrode/gas sample". It canbe necessary to catalytically convert the gas sample at the electrolyteside into such components which lead to an electrochemical reactionbecause of the applied measuring cell voltage. For this purpose, themeasuring electrode can be provided with a catalytic additive.

A further advantage is provided in that the measuring cell can beoperated in any desired position because of the permanent electrolytecontact to the measuring electrode.

It is especially advantageous to manufacture the protective disc from athermally-conductive electrically-insulating material and to determinethe permeable region with passages which specify the diffusion of thegas sample. The impermeable component region of the protective discfacing the ambient containing the gas sample carries electric contactpads which are contacted through to the electrodes. With these features,an advantageous temperature compensation for all of the electrodesdisposed on the electrolyte side of the protective disc is obtained sothat the temperature movement of the measuring result is avoided. At thesame time, the measuring cell can operate in the limiting diffusioncurrent region with the limiting diffusion current being determined bythe dimensions of the passages in coaction with the electrode activity.The passages can, for example, be configured as long and narrowdiffusion channels.

Since the material of the protective disc is electrically insulating, athrough-contact is possible in a simple manner which provides for anelectrical connection of the electrodes to the surface of the protectivedisc facing the ambient. A simple take-off of the measuring signal to anevaluation apparatus can be realized by a simple bonding of theconnecting leads to the contact pads of the upper surface.

Another possibility is that the connection to the contact pads duringassembly of the measuring cell can be produced in a suitable housing byappropriate contact pads functioning as measuring signal take-offs. Inboth cases, the need for passing the lead connections from theelectrodes through the measuring cell housing is avoided. Thiscontributes to a significant increase in the operational reliability ofthe measuring cell since slow leaks of the electrolyte which aredifficult to control and extend along the lead pass-throughs to thecontacts are avoided.

A contact mat made of a formed graphite fabric is provided in order torealize a nearly uniform contacting of the measuring electrode aspossible. The contact mat is on the one hand placed over the measuringelectrode on the side thereof facing the electrolyte and, on the otherhand, is led to the measuring contacts provided therefor on the side ofthe impermeable component region facing the electrolyte. The measuringelectrode is then packed between the diffusion membrane and thepermeable contact mat in a sandwich configuration. In this way, theapplication of electrical contacts for the measuring electrode on thethin and tear sensitive diffusion membrane is avoided and alarge-surface contact is provided.

To improve handling of the electrolyte, it is advantageously held in anabsorbent body which fills out the electrolyte chamber and is inpermanent contact with the electrodes. The only boundary of themeasuring cell to the ambient is defined by the protective disc. Theabsorbent body can be made of a sponge-like polyethylene body so that asimple configuration can be selected for the measuring cell housingwithout it being necessary to attend to special sealing problemsassociated with liquids. For example, the necessary ventilating openingsin the electrolyte chamber can be provided without the necessity ofadditional sealing measures with respect to the liquid.

The protective disc is made of a thermally-conductive material and hasan outer surface facing toward the ambient. For this configuration it isespecially advantageous to apply a temperature-sensitive element to thisouter surface at least around the permeable region or even thereacross.In this way, it is possible to detect almost precisely the temperatureof the gas sample present in the diffusion region and to then carry outa subsequent compensation of the measured value. It can be assumed thatthe gas sample has taken on the temperature of the sealing disc withsufficient accuracy during the diffusion through the permeable region.In this way, the temperature of the protective disc is suitable as acorrective factor to a good approximation.

The sealing disc can also advantageously be used as a carrier for apreamplifier circuit formed with hybrid technology. This leads to afurther miniaturization of the measuring cell and increases thesignal-to-noise ratio.

According to another feature of the invention, a porous gas distributionlayer is arranged behind the passages facing toward the membrane on theelectrolyte side in order to improve the distribution of the gas sample(diffusing through the permeable region) on the surface of the diffusionmembrane. This gas distribution layer is held by the diffusion membranethermally welded to the surface of the sealing disc facing theelectrolyte. A suitable method for thermally welding the diffusionmembrane made, for example, of polytetrafluoroethylene (PTFE) to ametallic or ceramic protective disc is disclosed in published Germanexamined patent application 2,311,096.

BRIEF DESCRIPTION OF THE DRAWING

The invention will now be described with reference to the single figureof the drawing which shows an embodiment of a measuring cell of theinvention, in section, but not drawn to scale because of its actualminiature size and the components thereof have increased dimensions toclearly show their relationship to each other.

DESCRIPTION OF THE PREFERRED EMBODIMENTS OF THE INVENTION

The measuring cell includes a pot-shaped housing 1 made of plastic whichis of circular shape. The measuring cell has an opening facing theambient which is covered by a protective disc 2 made of ceramic. Theinner chamber of the housing 1 is essentially filled by an absorbentbody 3 made of polyethylene in which the electrolyte 4 is accommodated.The ceramic disc 2 is penetrated in the center by a plurality ofpassages 5. The passages 5 have funnel-shaped inlets and outlets and areotherwise configured as capillary tubes which determine the diffusionrate of the gas sample diffusing into the measuring cell from theambient. The passages are shown by simple lines because of their reduceddiameter. The geometric location of the passages 5 defines the permeableregion 50 of the protective disc 2.

The component region 51 surrounding the permeable region 50 andextending to the edge of the circularly-shaped protective disc 2 definesthe impermeable region of the protective disc 2. A gas distributionlayer 6 is attached over the outlets of the passages 5 on theelectrolyte side of the protective disc 2 behind the passages 5. Thisgas distribution layer 6 covers a diffusion membrane 8 which is attachedto the weld edge 7. The diffusion membrane 8 carries the measuringelectrode 9 over which a contact mat 10 is pulled to the absorbent body3. The contact mat 10 is made of a formed graphite fabric and ispermeable The contact mat 10 realizes a nearly uniform contacting of themeasuring electrode 9 as possible and is bonded to the measuringcontacts 11. A counter electrode 12 and a reference electrode 13 areapplied to their respective contact pads (112, 113) also at theelectrolyte side on the inner surface of the protective, disc 2. Thecontact mat 10 as well as the contact pads (112, 113) of the counterelectrode 12 and the reference electrode 13, respectively, are inelectrical contact with the absorbent body 3.

The measuring contact 11 as well as the contact pads (112, 113) areconnected through to work contacts 14 on the outer surface of theprotective disc 2 facing the ambient. A ring-shapedtemperature-sensitive element 15 in the form of an NTC-resistor isapplied to this outer surface of the protective disc 2 in surroundingrelationship to the passages 5 of the permeable region 50. An amplifiercircuit 16 is schematically represented in the drawing and is disposedat the edge of the impermeable region 51. The amplifier circuit 16 canbe applied utilizing thin-film technology. The electrical signals fromthe work contact pads 14 as well as from the temperature-sensitiveelement 15 are conducted to this preamplifier circuit 16 via connectingleads (not shown) and processed before these signals are conducted to anevaluation and measuring unit (not shown).

The housing 1 is made of pliant plastic with the electrolyte chamberbeing connected with the ambient via a compensating opening 18. Theprotective disc 2 defines the boundary of the housing facing the gasatmosphere to be investigated. The protective disc can be held in aperipheral snap recess 19 and sealed with respect to the electrolytechamber 17 by an O-ring 20.

It is understood that the foregoing description is that of the preferredembodiments of the invention and that various changes and modificationsmay be made thereto without departing from the spirit and scope of theinvention as defined in the appended claims.

What is claimed is:
 1. A measuring cell for electrochemically detectinga gas sample, the measuring cell comprising:a housing having an openingdirected toward the gas sample to be detected and defining anelectrolyte chamber; an electrolyte contained in said chamber; ameasuring electrode and an counter electrode disposed in said chamber soas to be in spaced relationship to each other; a diffusion membraneinterposed between aid opening and said electrolyte and being permeableto the gas sample; said diffusion membrane being impermeable to saidelectrolyte and having a lower surface facing said electrolyte; saidmeasuring electrode being configured as a measuring electrode layerapplied to said lower surface of said diffusion membrane; said diffusionmembrane having an upper surface facing toward the gas sample; aprotective disc interposed between said opening and said upper surfaceof said diffusion membrane; said protective disc having a firstcomponent region permeable to the gas sample and a second componentregion impermeable to the gas sample and to said electrolyte; said firstcomponent region having an upper surface area directed toward the gassample and a lower surface area facing toward said electrolyte; saidfirst component region including a plurality of capillary passagesformed in said protective disc and extending between said upper andlower surface areas of said first component region; said secondcomponent region having a lower surface area facing toward saidelectrolyte and said counter electrode being configured as a counterelectrode layer applied to said lower surface area of said secondcomponent region; said counter electrode layer being electricallyisolated from said measuring electrode and being in permanent electricalcontact with said electrolyte; said measuring electrode layer and saiddiffusion membrane being applied to said lower surface area of saidfirst component region of said protective disc so as to communicate withsaid capillary passages; said protective disc being made ofthermally-conductive electrically-insulating material; said capillarypassages being dimensioned to determined the diffusion of the gassample; said second component region having an upper surface area facingthe gas sample; and, the measuring cell further comprising workingcontact pads formed on said upper surface area of said second componentregion and being connected through said protective disc to respectiveones of said electrodes.
 2. The measuring cell of claim 1, furthercomprising: a contact mat for interconnecting said measuring electrodelayer to the one working contact pad corresponding thereto; an ancillarymeasuring contact applied to said lower surface area of said secondcomponent region and being through connected to said one workingcontact; and said contact mat extending over said measuring electrodelayer between said measuring electrode layer and said electrolyte andbeing connected to said ancillary measuring contact.
 3. A measuring cellfor electrochemically detecting a gas sample, the measuring cellcomprising:a housing having an opening directed toward the gas sample tobe detected and defining an electrolyte chamber; an electrolytecontained in said chamber; a measuring electrode and a counter electrodedisposed in said chamber so as to be in spaced relationship to eachother; a diffusion membrane interposed between said opening and saidelectrolyte and being permeable to the gas sample; said diffusionmembrane being impermeable to said electrolyte and having a lowersurface facing said electrolyte; said measuring electrode beingconfigured as a measuring electrode layer applied to said lower surfaceof said diffusion membrane; said diffusion membrane having an uppersurface facing toward the gas sample; a protective disc made of ceramicand being interposed between said opening and said upper surface of saiddiffusion membrane; said protective disc having a first component regionpermeable to the gas sample and a second component region impermeable tothe gas sample and to said electrolyte; said first component regionhaving an upper surface area directed toward the gas sample and a lowersurface area facing toward said electrolyte; said first component regionincluding a plurality of capillary passages formed in said protectivedisc and extending between said upper and lower surface areas of saidfirst component region; said second component region having a lowersurface area facing toward said electrolyte and said counter electrodebeing configured as a counter electrode layer applied to said lowersurface area of said second component region; said counter electrodelayer being electrically isolated from said measuring electrode andbeing in permanent electrical contact with said electrolyte; and saidmeasuring electrode layer and said diffusion membrane being applied tosaid lower surface area of said first component region of saidprotective disc so as to communicate with said capillary passages.